dlib C++ Library - optimization_abstract.h

// Copyright (C) 2008 Davis E. King (davis@dlib.net)
// License: Boost Software License See LICENSE.txt for the full license.
#undef DLIB_OPTIMIZATIOn_ABSTRACT_
#ifdef DLIB_OPTIMIZATIOn_ABSTRACT_
#include <cmath>
#include <limits>
#include "../matrix/matrix_abstract.h"
#include "../algs.h"
#include "optimization_search_strategies_abstract.h"
#include "optimization_stop_strategies_abstract.h"
#include "optimization_line_search_abstract.h"
namespace dlib
{
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
// Functions that transform other functions 
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
 template <
 typename funct
 >
 class central_differences;
 /*!
 This is a function object that represents the derivative of some other
 function. 
 Note that if funct is a function of a double then the derivative of 
 funct is just a double but if funct is a function of a dlib::matrix (i.e. a
 function of many variables) then its derivative is a gradient vector (a column
 vector in particular).
 !*/
 template <
 typename funct
 >
 const central_differences<funct> derivative(
 const funct& f, 
 double eps
 );
 /*!
 requires
 - f == a function that returns a scalar
 - f must have one of the following forms:
 - double f(double)
 - double f(dlib::matrix) (where the matrix is a column vector)
 - double f(T, dlib::matrix) (where the matrix is a column vector. In 
 this case the derivative of f is taken with respect to the second argument.)
 - eps > 0
 ensures
 - returns a function that represents the derivative of the function f. It
 is approximated numerically by:
 (f(x+eps)-f(x-eps))/(2*eps)
 !*/
 template <
 typename funct
 >
 const central_differences<funct> derivative(
 const funct& f
 );
 /*!
 ensures
 - returns derivative(f, 1e-7)
 !*/
// ----------------------------------------------------------------------------------------
 template <
 typename funct, 
 typename EXP1, 
 typename EXP2
 >
 clamped_function_object<funct,EXP1,EXP2> clamp_function (
 const funct& f,
 const matrix_exp<EXP1>& x_lower,
 const matrix_exp<EXP2>& x_upper 
 );
 /*!
 requires
 - f == a function that takes a matrix and returns a scalar value. Moreover, f
 must be capable of taking in matrices with the same dimensions as x_lower and
 x_upper. So f(x_lower) must be a valid expression that evaluates to a scalar
 value.
 - x_lower.nr() == x_upper.nr() && x_lower.nc() == x_upper.nc()
 (i.e. x_lower and x_upper must have the same dimensions)
 - x_lower and x_upper must contain the same type of elements.
 ensures
 - returns a function object that represents the function g(x) where
 g(x) == f(clamp(x,x_lower,x_upper))
 !*/
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
// Functions that perform unconstrained optimization 
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
 template <
 typename search_strategy_type,
 typename stop_strategy_type,
 typename funct, 
 typename funct_der, 
 typename T
 >
 double find_min (
 search_strategy_type search_strategy,
 stop_strategy_type stop_strategy,
 const funct& f, 
 const funct_der& der, 
 T& x, 
 double min_f
 );
 /*!
 requires
 - search_strategy == an object that defines a search strategy such as one 
 of the objects from dlib/optimization/optimization_search_strategies_abstract.h
 - stop_strategy == an object that defines a stop strategy such as one of 
 the objects from dlib/optimization/optimization_stop_strategies_abstract.h
 - f(x) must be a valid expression that evaluates to a double
 - der(x) must be a valid expression that evaluates to the derivative of f() at x.
 - is_col_vector(x) == true
 ensures
 - Performs an unconstrained minimization of the function f() using the given
 search_strategy and starting from the initial point x. 
 - The function is optimized until stop_strategy decides that an acceptable 
 point has been found or f(#x) < min_f.
 - #x == the value of x that was found to minimize f()
 - returns f(#x). 
 - When this function makes calls to f() and der() it always does so by
 first calling f() and then calling der(). That is, these two functions
 are always called in pairs with f() being called first and then der()
 being called second.
 !*/
// ----------------------------------------------------------------------------------------
 template <
 typename search_strategy_type,
 typename stop_strategy_type,
 typename funct, 
 typename funct_der, 
 typename T
 >
 double find_max (
 search_strategy_type search_strategy,
 stop_strategy_type stop_strategy,
 const funct& f, 
 const funct_der& der, 
 T& x, 
 double max_f
 );
 /*!
 requires
 - search_strategy == an object that defines a search strategy such as one 
 of the objects from dlib/optimization/optimization_search_strategies_abstract.h
 - stop_strategy == an object that defines a stop strategy such as one of 
 the objects from dlib/optimization/optimization_stop_strategies_abstract.h
 - f(x) must be a valid expression that evaluates to a double
 - der(x) must be a valid expression that evaluates to the derivative of f() at x.
 - is_col_vector(x) == true
 ensures
 - Performs an unconstrained maximization of the function f() using the given
 search_strategy and starting from the initial point x. 
 - The function is optimized until stop_strategy decides that an acceptable 
 point has been found or f(#x) > max_f.
 - #x == the value of x that was found to maximize f()
 - returns f(#x). 
 - When this function makes calls to f() and der() it always does so by
 first calling f() and then calling der(). That is, these two functions
 are always called in pairs with f() being called first and then der()
 being called second.
 - Note that this function solves the maximization problem by converting it 
 into a minimization problem. Therefore, the values of f and its derivative
 reported to the stopping strategy will be negated. That is, stop_strategy
 will see -f() and -der(). All this really means is that the status messages
 from a stopping strategy in verbose mode will display a negated objective
 value.
 !*/
// ----------------------------------------------------------------------------------------
 template <
 typename search_strategy_type,
 typename stop_strategy_type,
 typename funct,
 typename T
 >
 double find_min_using_approximate_derivatives (
 search_strategy_type search_strategy,
 stop_strategy_type stop_strategy,
 const funct& f,
 T& x,
 double min_f,
 double derivative_eps = 1e-7
 );
 /*!
 requires
 - search_strategy == an object that defines a search strategy such as one 
 of the objects from dlib/optimization/optimization_search_strategies_abstract.h
 - stop_strategy == an object that defines a stop strategy such as one of 
 the objects from dlib/optimization/optimization_stop_strategies_abstract.h
 - f(x) must be a valid expression that evaluates to a double
 - is_col_vector(x) == true
 - derivative_eps > 0 
 ensures
 - Performs an unconstrained minimization of the function f() using the given
 search_strategy and starting from the initial point x. 
 - The function is optimized until stop_strategy decides that an acceptable 
 point has been found or f(#x) < min_f.
 - #x == the value of x that was found to minimize f()
 - returns f(#x). 
 - Uses the dlib::derivative(f,derivative_eps) function to compute gradient
 information.
 !*/
// ----------------------------------------------------------------------------------------
 template <
 typename search_strategy_type,
 typename stop_strategy_type,
 typename funct,
 typename T
 >
 double find_max_using_approximate_derivatives (
 search_strategy_type search_strategy,
 stop_strategy_type stop_strategy,
 const funct& f,
 T& x,
 double max_f,
 double derivative_eps = 1e-7
 );
 /*!
 requires
 - search_strategy == an object that defines a search strategy such as one 
 of the objects from dlib/optimization/optimization_search_strategies_abstract.h
 - stop_strategy == an object that defines a stop strategy such as one of 
 the objects from dlib/optimization/optimization_stop_strategies_abstract.h
 - f(x) must be a valid expression that evaluates to a double
 - is_col_vector(x) == true
 - derivative_eps > 0 
 ensures
 - Performs an unconstrained maximization of the function f() using the given
 search_strategy and starting from the initial point x. 
 - The function is optimized until stop_strategy decides that an acceptable 
 point has been found or f(#x) > max_f.
 - #x == the value of x that was found to maximize f()
 - returns f(#x). 
 - Uses the dlib::derivative(f,derivative_eps) function to compute gradient
 information.
 - Note that this function solves the maximization problem by converting it 
 into a minimization problem. Therefore, the values of f and its derivative
 reported to the stopping strategy will be negated. That is, stop_strategy
 will see -f() and -der(). All this really means is that the status messages
 from a stopping strategy in verbose mode will display a negated objective
 value.
 !*/
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
// Functions that perform box constrained optimization 
// ----------------------------------------------------------------------------------------
// ----------------------------------------------------------------------------------------
 template <
 typename search_strategy_type,
 typename stop_strategy_type,
 typename funct, 
 typename funct_der, 
 typename T,
 typename EXP1,
 typename EXP2
 >
 double find_min_box_constrained (
 search_strategy_type search_strategy,
 stop_strategy_type stop_strategy,
 const funct& f, 
 const funct_der& der, 
 T& x,
 const matrix_exp<EXP1>& x_lower,
 const matrix_exp<EXP2>& x_upper
 );
 /*!
 requires
 - search_strategy == an object that defines a search strategy such as one 
 of the objects from dlib/optimization/optimization_search_strategies_abstract.h
 - stop_strategy == an object that defines a stop strategy such as one of 
 the objects from dlib/optimization/optimization_stop_strategies_abstract.h
 - f(x) must be a valid expression that evaluates to a double
 - der(x) must be a valid expression that evaluates to the derivative of f() at x.
 - is_col_vector(x) == true
 - is_col_vector(x_lower) == true
 - is_col_vector(x_upper) == true
 - x.size() == x_lower.size() == x_upper.size()
 (i.e. x, x_lower, and x_upper need to all be column vectors of the same dimensionality)
 - min(x_upper-x_lower) >= 0
 (i.e. x_upper must contain upper bounds relative to x_lower)
 ensures
 - Performs a box constrained minimization of the function f() using the given
 search_strategy and starting from the initial point x. That is, we try to
 find the x value that minimizes f(x) but is also within the box constraints 
 specified by x_lower and x_upper. That is, we ensure that #x satisfies: 
 - min(#x - x_lower) >= 0 && min(x_upper - #x) >= 0
 - This function uses a backtracking line search along with a gradient projection
 step to handle the box constraints.
 - The function is optimized until stop_strategy decides that an acceptable
 point has been found. 
 - #x == the value of x that was found to minimize f() within the given box
 constraints.
 - returns f(#x). 
 - The last call to f() will be made with f(#x). 
 - When calling f() and der(), the input passed to them will always be inside
 the box constraints defined by x_lower and x_upper.
 - When calling der(x), it will always be the case that the last call to f() was
 made with the same x value. This means that you can reuse any intermediate
 results from the previous call to f(x) inside der(x) rather than recomputing
 them inside der(x).
 !*/
// ----------------------------------------------------------------------------------------
 template <
 typename search_strategy_type,
 typename stop_strategy_type,
 typename funct, 
 typename funct_der, 
 typename T
 >
 double find_min_box_constrained (
 search_strategy_type search_strategy,
 stop_strategy_type stop_strategy,
 const funct& f, 
 const funct_der& der, 
 T& x,
 const double x_lower,
 const double x_upper
 );
 /*!
 requires
 - search_strategy == an object that defines a search strategy such as one 
 of the objects from dlib/optimization/optimization_search_strategies_abstract.h
 - stop_strategy == an object that defines a stop strategy such as one of 
 the objects from dlib/optimization/optimization_stop_strategies_abstract.h
 - f(x) must be a valid expression that evaluates to a double
 - der(x) must be a valid expression that evaluates to the derivative of f() at x.
 - is_col_vector(x) == true
 - x_lower < x_upper
 ensures
 - This function is identical to find_min_box_constrained() as defined above
 except that it takes x_lower and x_upper as doubles rather than column
 vectors. In this case, all variables have the same lower bound of x_lower
 and similarly have the same upper bound of x_upper. Therefore, this is just
 a convenience function for calling find_max_box_constrained() when all
 variables have the same bound constraints.
 !*/
// ----------------------------------------------------------------------------------------
 template <
 typename search_strategy_type,
 typename stop_strategy_type,
 typename funct, 
 typename funct_der, 
 typename T,
 typename EXP1,
 typename EXP2
 >
 double find_max_box_constrained (
 search_strategy_type search_strategy,
 stop_strategy_type stop_strategy,
 const funct& f, 
 const funct_der& der, 
 T& x,
 const matrix_exp<EXP1>& x_lower,
 const matrix_exp<EXP2>& x_upper
 );
 /*!
 requires
 - search_strategy == an object that defines a search strategy such as one 
 of the objects from dlib/optimization/optimization_search_strategies_abstract.h
 - stop_strategy == an object that defines a stop strategy such as one of 
 the objects from dlib/optimization/optimization_stop_strategies_abstract.h
 - f(x) must be a valid expression that evaluates to a double
 - der(x) must be a valid expression that evaluates to the derivative of f() at x.
 - is_col_vector(x) == true
 - is_col_vector(x_lower) == true
 - is_col_vector(x_upper) == true
 - x.size() == x_lower.size() == x_upper.size()
 (i.e. x, x_lower, and x_upper need to all be column vectors of the same dimensionality)
 - min(x_upper-x_lower) >= 0
 (i.e. x_upper must contain upper bounds relative to x_lower)
 ensures
 - Performs a box constrained maximization of the function f() using the given
 search_strategy and starting from the initial point x. That is, we try to
 find the x value that maximizes f(x) but is also within the box constraints 
 specified by x_lower and x_upper. That is, we ensure that #x satisfies: 
 - min(#x - x_lower) >= 0 && min(x_upper - #x) >= 0
 - This function uses a backtracking line search along with a gradient projection
 step to handle the box constraints.
 - The function is optimized until stop_strategy decides that an acceptable
 point has been found. 
 - #x == the value of x that was found to maximize f() within the given box
 constraints.
 - returns f(#x). 
 - The last call to f() will be made with f(#x). 
 - When calling f() and der(), the input passed to them will always be inside
 the box constraints defined by x_lower and x_upper.
 - When calling der(x), it will always be the case that the last call to f() was
 made with the same x value. This means that you can reuse any intermediate
 results from the previous call to f(x) inside der(x) rather than recomputing
 them inside der(x).
 - Note that this function solves the maximization problem by converting it 
 into a minimization problem. Therefore, the values of f and its derivative
 reported to the stopping strategy will be negated. That is, stop_strategy
 will see -f() and -der(). All this really means is that the status messages
 from a stopping strategy in verbose mode will display a negated objective
 value.
 !*/
// ----------------------------------------------------------------------------------------
 
 template <
 typename search_strategy_type,
 typename stop_strategy_type,
 typename funct, 
 typename funct_der, 
 typename T
 >
 double find_max_box_constrained (
 search_strategy_type search_strategy,
 stop_strategy_type stop_strategy,
 const funct& f, 
 const funct_der& der, 
 T& x,
 const double x_lower,
 const double x_upper
 );
 /*!
 requires
 - search_strategy == an object that defines a search strategy such as one 
 of the objects from dlib/optimization/optimization_search_strategies_abstract.h
 - stop_strategy == an object that defines a stop strategy such as one of 
 the objects from dlib/optimization/optimization_stop_strategies_abstract.h
 - f(x) must be a valid expression that evaluates to a double
 - der(x) must be a valid expression that evaluates to the derivative of f() at x.
 - is_col_vector(x) == true
 - x_lower < x_upper
 ensures
 - This function is identical to find_max_box_constrained() as defined above
 except that it takes x_lower and x_upper as doubles rather than column
 vectors. In this case, all variables have the same lower bound of x_lower
 and similarly have the same upper bound of x_upper. Therefore, this is just
 a convenience function for calling find_max_box_constrained() when all
 variables have the same bound constraints.
 !*/
// ----------------------------------------------------------------------------------------
}
#endif // DLIB_OPTIMIZATIOn_ABSTRACT_